This paper presents a thorough study of the chassis design, material selection, and structural analysis of an electric scooter chassis, providing valuable insights into its critical role in modern electric vehicle applications. The chassis, forming the backbone of the vehicle, is crucial for providing structural support and ensuring the stability and safety of the vehicle, its internal components, and its accessory parts. We have made meticulous decisions focusing on the material selection, opting for the most robust, and our specifications, and referring to online sources and papers to identify a rider-friendly design and overall frame stability. The chassis's role is to provide structural support, and safety, facilitate component integration, and significantly contribute to the vehicle's overall functionality and competitive edge in the market. To further enhance the design, we have considered various design parameters, including strength and rigidity, weight reduction, manufacturing feasibility, driver ergonomics, safety, component integration capability, cost-effectiveness, and aesthetics. The chassis must withstand the maximum dynamic loads, keep the driver safe on different terrains, maintain a balanced weight distribution, and comply with all safety regulations. Advanced modeling using SOLIDWORKS and simulations (FEM) is employed to test the integrity and reliability of the chassis under various loading conditions, stresses, and impacts. These simulations include structural analysis, front impact analysis, side impact analysis, and rear impact analysis, all conducted using ANSYS software to ensure reliable performance. The design process adheres strictly to the guidelines set forth by the SAEINDIA electric two-wheeler design competition rulebook, ensuring compliance with industry standards.